Function

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Overview

Binds peptides derived from antigens that access the endocytic route of antigen presenting cells (APC) and presents them on the cell surface for recognition by the CD4 T-cells. The peptide binding cleft accommodates peptides of 10-30 residues. The peptides presented by MHC class II molecules are generated mostly by degradation of proteins that access the endocytic route, where they are processed by lysosomal proteases and other hydrolases. Exogenous antigens that have been endocytosed by the APC are thus readily available for presentation via MHC II molecules, and for this reason this antigen presentation pathway is usually referred to as exogenous. As membrane proteins on their way to degradation in lysosomes as part of their normal turn-over are also contained in the endosomal/lysosomal compartments, exogenous antigens must compete with those derived from endogenous components. Autophagy is also a source of endogenous peptides, autophagosomes constitutively fuse with MHC class II loading compartments. In addition to APCs, other cells of the gastrointestinal tract, such as epithelial cells, express MHC class II molecules and CD74 and act as APCs, which is an unusual trait of the GI tract. To produce a MHC class II molecule that presents an antigen, three MHC class II molecules (heterodimers of an alpha and a beta chain) associate with a CD74 trimer in the ER to form a heterononamer. Soon after the entry of this complex into the endosomal/lysosomal system where antigen processing occurs, CD74 undergoes a sequential degradation by various proteases, including CTSS and CTSL, leaving a small fragment termed CLIP (class-II-associated invariant chain peptide). The removal of CLIP is facilitated by HLA-DM via direct binding to the alpha-beta-CLIP complex so that CLIP is released. HLA-DM stabilizes MHC class II molecules until primary high affinity antigenic peptides are bound. The MHC II molecule bound to a peptide is then transported to the cell membrane surface. In B-cells, the interaction between HLA-DM and MHC class II molecules is regulated by HLA-DO. Primary dendritic cells (DCs) also to express HLA-DO. Lysosomal microenvironment has been implicated in the regulation of antigen loading into MHC II molecules, increased acidification produces increased proteolysis and efficient peptide loading.

Analysis of the frequencies of class II HLA-DR and HLA-DQ alleles by serological and DNA typing in 49 Japanese patients with type 1 (insulin-dependent) diabetes and 31 Japanese controls indicates the following. (i) Susceptibility is more strongly associated with the HLA-DQ subregion than with the HLA-DR subregion. (ii) Of the class II alleles detected, the A3 allele of the DQA1 locus was the most strongly associated with disease. Ninety-six percent of the patients were positive for the A3 allele compared to 53% of the controls (P = 0.001; relative risk = 19.7; confidence limits = 3.72-188.64). (iii) The DQw8 allele of the DQB1 locus, which is associated with susceptibility to type 1 diabetes in Caucasians and Blacks, was not increased in frequency in Japanese patients (22%) versus controls (19%). (iv) Asp-57-encoding DQB1 alleles are associated with reduced susceptibility to type 1 diabetes in Caucasians. The major predisposing haplotypes in Japanese are DR4 and DR9. By DNA sequence analysis, both of these Japanese haplotypes have Asp-57-encoding DQB1 alleles. Oligonucleotide dot blot analysis showed that all, except 1, of the 49 Japanese patients and all of the 31 controls have at least one Asp-57-encoding DQB1 allele. In addition, 40% of the patients were homozygous for Asp-57-encoding DQB1 alleles versus 35% of the controls. The high frequencies of Asp-57-encoding DQB1 alleles in this ethnic group may account for the rarity of type 1 diabetes in Japan.

The HLA-D region is composed of three subregions termed DR, DQ, and DP. We previously reported the sequence of a DR5 beta I and two DR5 beta III cDNA from the DR5 cell line Swei. We now report on the nucleotide and deduced amino acid sequence of the DQ alpha and DQ beta cDNA from the same DR5 cell line, which also types as DQw3. Comparison with other available DQ sequences indicates that DQ alpha has one region of major variability, whereas DQ beta appears to have four regions of variability. In addition, these comparisons indicate that DQw3 alpha from DR5 is different from DQw3 alpha from DR4, but identical to DQw2 alpha from DR3. In contrast, DQw3 beta from DR5 is very similar to DQw3 beta from DR4. These data indicate that at least for DQw2 and DQw3 it is the DQ beta chain that is responsible for DQ typing. Most sequence differences in DQ alleles can be attributed to point mutations; however, codon additions/deletions in the DQ alpha chain may contribute to variability. In addition, regions of possible gene conversion in the DQ alpha and DQ beta chains is suggested by the presence of a chi-like sequence in each chain. Finally, comparison of available haplotypes suggest recombination events may take place between DQ beta and DQ alpha, between DQ alpha and DR beta I, and between DR beta I and DR beta III.

The HLA-D region of the major histocompatibility complex (MHC) of man encodes polymorphic glycoproteins found predominantly on the cell surfaces of B cells and macrophages. These proteins mediate interactions, required for the induction of immune responses, among cells of the immune system and consequently are referred to as Ia (immune-response associated). Two families of Ia molecules, DR and DS (also known as DC), have been defined, the former analogous to the I-E (ref. 1) and the latter to the I-A molecules of the murine MHC. Both DR and DS molecules consist of two noncovalently associated polypeptide chains with molecular weights of 33,000 and 28,000, designated alpha and beta, respectively. The polymorphism of DR molecules is due to structural variation in the small subunit, DR beta, with the large subunit, DR alpha, being constant in structure. In contrast, both subunits DS alpha and DS beta are structurally variable when DS allotypes are compared. We have now isolated a cDNA clone from a DR7 cell line that contains the entire coding sequence for the DS alpha subunit and have compared its predicted amino acid sequence with that previously deduced from a DS alpha cDNA clone isolated from a DR4,w6 cell line. This comparison reveals that 10 of 11 amino acid differences are located within the alpha 1 (N-terminal) domain and that the alpha 2 or immunoglobulin-like domains are identical.

Chronic beryllium disease (CBD) is a fibrotic lung disorder caused by beryllium (Be) exposure and is characterized by granulomatous inflammation and the accumulation of Be-responsive CD4(+) T cells in the lung. Genetic susceptibility to CBD has been associated with certain alleles of the MHCII molecule HLA-DP, especially HLA-DPB1*0201 and other alleles that contain a glutamic acid residue at position 69 of the beta-chain (betaGlu69). The HLA-DP alleles that can present Be to T cells match those implicated in the genetic susceptibility, suggesting that the HLA contribution to disease is based on the ability of those molecules to bind and present Be to T cells. The structure of HLA-DP2 and its interaction with Be are unknown. Here, we present the HLA-DP2 structure with its antigen-binding groove occupied by a self-peptide derived from the HLA-DR alpha-chain. The most striking feature of the structure is an unusual solvent exposed acidic pocket formed between the peptide backbone and the HLA-DP2 beta-chain alpha-helix and containing three glutamic acids from the beta-chain, including betaGlu69. In the crystal packing, this pocket has been filled with the guanidinium group of an arginine from a neighboring molecule. This positively charged moiety forms an extensive H-bond/salt bridge network with the three glutamic acids, offering a plausible model for how Be-containing complexes might occupy this site. This idea is strengthened by the demonstration that mutation of any of the three glutamic acids in this pocket results in loss of the ability of DP2 to present Be to T cells.

The HLA-D region is composed of three subregions termed DR, DQ, and DP. We previously reported the sequence of a DR5 beta I and two DR5 beta III cDNA from the DR5 cell line Swei. We now report on the nucleotide and deduced amino acid sequence of the DQ alpha and DQ beta cDNA from the same DR5 cell line, which also types as DQw3. Comparison with other available DQ sequences indicates that DQ alpha has one region of major variability, whereas DQ beta appears to have four regions of variability. In addition, these comparisons indicate that DQw3 alpha from DR5 is different from DQw3 alpha from DR4, but identical to DQw2 alpha from DR3. In contrast, DQw3 beta from DR5 is very similar to DQw3 beta from DR4. These data indicate that at least for DQw2 and DQw3 it is the DQ beta chain that is responsible for DQ typing. Most sequence differences in DQ alleles can be attributed to point mutations; however, codon additions/deletions in the DQ alpha chain may contribute to variability. In addition, regions of possible gene conversion in the DQ alpha and DQ beta chains is suggested by the presence of a chi-like sequence in each chain. Finally, comparison of available haplotypes suggest recombination events may take place between DQ beta and DQ alpha, between DQ alpha and DR beta I, and between DR beta I and DR beta III.

The HLA-D region of the major histocompatibility complex (MHC) of man encodes polymorphic glycoproteins found predominantly on the cell surfaces of B cells and macrophages. These proteins mediate interactions, required for the induction of immune responses, among cells of the immune system and consequently are referred to as Ia (immune-response associated). Two families of Ia molecules, DR and DS (also known as DC), have been defined, the former analogous to the I-E (ref. 1) and the latter to the I-A molecules of the murine MHC. Both DR and DS molecules consist of two noncovalently associated polypeptide chains with molecular weights of 33,000 and 28,000, designated alpha and beta, respectively. The polymorphism of DR molecules is due to structural variation in the small subunit, DR beta, with the large subunit, DR alpha, being constant in structure. In contrast, both subunits DS alpha and DS beta are structurally variable when DS allotypes are compared. We have now isolated a cDNA clone from a DR7 cell line that contains the entire coding sequence for the DS alpha subunit and have compared its predicted amino acid sequence with that previously deduced from a DS alpha cDNA clone isolated from a DR4,w6 cell line. This comparison reveals that 10 of 11 amino acid differences are located within the alpha 1 (N-terminal) domain and that the alpha 2 or immunoglobulin-like domains are identical.

Keywords

Protein involved in immunity, any immune system process that functions in the response of an organism to a potential internal or invasive threat. The vertebrate immune system is formed by the innate immune system (composed of phagocytes, complement, antimicrobial peptides, etc) and by the adaptive immune system which consists of T- and B- lymphocytes.

Protein which is part of a reference proteome. Reference proteomes are a subset of proteomes that have been selected either manually or algorithmically according to a number of criteria to provide a broad coverage of the tree of life and a representative cross-section of the taxonomic diversity found within UniProtKB, as well as the proteomes of well-studied model organisms and other species of interest for biomedical research.